SE446574B - LAGTRYCKSKVICKSILVERANGURLADDNINGSLAMPA - Google Patents

Description

4461574, it is also possible to provide the inner element with a reflective layer between the luminescent layer and the wall of the element to prevent loss of light towards the interior of the lamp, where a stabilization ballast is located.

A disadvantage of the known lamp is that dark strips become visible on the outside of the lamp at the parts which lie between the grooves, since these parts do not contribute to the emission of light. This results in a less attractive appearance of the lamp and has a detrimental effect on the light flux of the lamp. Although the risk of short-circuiting the discharge is reduced by the fact that both bodies are conical, it is also possible that the luminescent layer or the reflective layer is damaged when the inner element is pushed into the outer element.

It is an object of the invention to provide a low pressure mercury vapor discharge lamp which is easy to produce, has a high luminous flux per lamp volume unit, as well as having such a shape that it can be easily used in conventional luminaires for ordinary light bulbs.

According to the invention, a low-pressure mercury vapor discharge lamp of the type indicated in the introduction is characterized in that said intermediate parts located between the groove parts face and extend parallel to the opposite parts of the wall of the second element, and that these intermediate parts and the opposite parts of the second element are free. luminescent material.

A lamp according to the invention has a high luminous flux per lamp volume unit because the light can leave the lamp unobstructed in substantially all directions, thus also the light emitted in the direction of the longitudinal axis of the lamp. This follows from the fact that the ultraviolet mercury resonance radiation; which is converted into visible light by the luminescent layers lying on the wall of the grooves, leaves the lamp through the hollow space inside the inner element and through the end surfaces. This results in a kind of light output window.

Said end surfaces of the grooved element extend to or close to the wall of the second electricity emeritus. Both elements can abut against each other at the end surfaces, but this is not necessary. Preferably, there is a gap of at most 2 mm between the end surfaces and the second element. With such a gap, the discharge chamber is closed in a discharge-tight manner, i.e. no short circuit of the discharge can occur through the gap. An advantage of this embodiment is that the two elements can be pushed onto each other during the manufacture of the lamp without damaging the luminescent layers. The two elements thus only need to be sealed in a gas-tight manner near the ends, e.g. medium pc sealing glass. In addition, the presence of said gap facilitates the so-called The "pumping" (evacuation) of the lamps during production. Such a direct current lamp has the additional advantage that the depletion of mercury at the anode is due to the fact that the (positive) mercury ions have moved towards the cathode. during lamp operation (cataphoresis effect) is counteracted by mercury transport through the narrow gap towards the anode zone.

The clamping pattern arranged on one of the elements determines the final shape of the discharge path. In general, it is advantageous for the luminous flux and efficiency of the compact discharge lamps that the discharge path is relatively long.

Preferably, the grooves (and consequently the end faces) of a lamp according to the invention have the shape of a spiral or the grooves extend substantially in the longitudinal direction of the lamp.

The groove pattern can be arranged in the outer element, the inner element usually having a cylindrical shape. In such an embodiment, the discharge path is limited by the walls to the parts which are located between the grooves in the outer element and the outer surface of the inner element. In a preferred embodiment of a lamp according to the invention, however, the inner element is provided with grooves, while the outer element consists of a cylindrical lamp housing. These lamps do not become fragile because the grooves are located in the inner body.

. Measured along the circumference of the inner body, the width of the grooves in lamp types having longitudinal grooves is preferably approximately equal to the width of the end surfaces. It has been found that the luminous flux per lamp volume unit is optimal in this condition.

In another embodiment of the lamp according to the invention there is a reflecting element in the inner element. The reflecting element consists, for example, of a glass tube which is coated on the outside with a reflective layer, such as magnesium oxide. Alternatively, the reflective element may consist of aluminum. A lamp with this construction has a very even light distribution. The light flux can be increased and the even light distribution can be improved by grooving the reflecting element in the direction of the end surfaces (the intermediate parts). In this way, the visible light, which is converted by the luminescent layers and is directed towards the longitudinal axis of the lamps, is reflected towards said end surfaces (the "light output windows"). Such hollow reflecting elements provide sufficient space for an electrical stabilization ballast and / or a starting device. It is not necessary to take extra measures to install these electrical units in the light bulb luminaire itself. A special embodiment of a lamp according to the invention is characterized in that the intermediate parts and / or the opposite wall parts of the second element which are "Bëlïçfna opposite the intermediate parts have a refractive profile. This profile, which can either be arranged on the inner wall or the outer wall, consists, for example, of a pattern of tubes which extend parallel to the discharge path and have a prismatic cross-section.

- The light rays coming from the grooves and transmitted towards the end surfaces are thereby refracted so that a lamp with an even light distribution and a high brightness is obtained.

Alternatively, it is possible that the refractive profile consists of frosted glass with a high transmission coefficient of light. Lamps according to the invention can be used as an alternative to incandescent lamps.

In addition to the fact that the dimensions are of the same order of magnitude for incandescent lamps, the efficiency of the discharge lamps is many times higher. By a suitable choice of the luminescent material, it is possible in lamps according to the invention to achieve a color temperature which substantially corresponds to the color temperature of the light bulb. This makes it attractive to use discharge lamps according to the invention in living rooms.

Embodiments of the invention will now be explained by way of example with reference to the drawings, in which Fig. 1 shows a compact low pressure mercury discharge lamp in which the inner element is provided with grooves extending in the longitudinal direction of the lamp, Fig. 2 shows a side view of the same lamp, Fig. 3 Fig. 5 shows a cross-section taken along the line III-III through the lamp according to Fig. 1, Fig. 4 shows a cross-section through a lamp according to the invention in which the inner element has six grooves, Fig. 5 shows a cross-section through a lamp according to Fig. 1 or 2 , in which a reflector is arranged inside the inner element, Fig. 6 schematically shows a longitudinal section through an embodiment of a lamp according to the invention, in which the outer element has a helical groove pattern, Fig. 7 shows a cross section according to Fig. 3, the end surfaces having seen with a refractive profile and Fig. 8 shows a cross section as in Fig. 3, wherein a refractive profile has been arranged on the parts of the outer wall of the outer body which are devote opposite the end faces.

The lamp shown in Fig. 1 comprises a cylindrical lamp housing 1. The lamp housing contains a hollow cylindrical inner element 2 of glass which in the longitudinal direction is provided with four grooves, two of which (3 and 4) are shown in Fig. 1. The discharge path runs in a pleated path. between electrodes 5 and 6 and is limited by the walls of the grooves and the lamp housing. Only the grooves and the parts of the lamp housing facing the discharge are covered with a layer of luminescent material, which consists of a mixture of three phosphorus substances, n, fl again blue luminescent bivalent europium-activated barium-magnesium aluminate; green luminescent terbium-activated cerium-magnesium aluminate and red luminescent trivalent europium-activated yttrium oxide. The intermediate parts or end surfaces (a front view of one of these parts or end surfaces is shown in the drawing where it is indicated by 7) of the inner element 2, which are located between the grooves, extend almost to the wall of the lamp housing 1 and are parallel to this. These intermediate parts and the parts of the lamp housing facing them are free of luminescent material (see also Fig. 3). In this way, these parts form "light output windows". In a special embodiment, the lamp is approximately 12 cm long.

The diameter of the lamp housing is approximately 5.5 cm. The depth of the grooves in which the discharge is located is approximately 1.5 cm. The end surfaces are 1.8 cm wide. The total length of the discharge path is approximately 40 cm. The intermediate portion 7 lying between the two electrodes is at a distance of 0.2 mm from the wall of the lamp envelope 1, while the remaining intermediate portions (7a) are separated by approximately 1.0 mm from the lamp envelope. The lamp contains mercury at a pressure of 6 x 10 ° 3 dry together with a noble gas mixture of argon and neon (75-25 vol.%) At a pressure of 2.5 torr. At a power supply of 25 watts to the lamp and an operating voltage of 100 V, the lamp had an efficiency of 63 lm / H. The lamp base 8 has a run for an electrical stabilization ball and / or a starting device. A contact sleeve 9 is attached to the lamp socket so that the lamp can be mounted in an annature for incandescent lamps.

Fig. 2 shows a side view of a lamp according to Fig. 1. The reference numerals are the same as in Fig. 1. The discharge path goes from the electrode 5 upwards through the groove É and downwards through the groove 10, transversely through an opening 11 and upwards via another groove (not shown), after which it again goes down towards the second electrode (6) via the groove 4.

Fig. 3 shows a cross section through a lamp according to Fig. 1 taken along the line III-III. The hollow inner element 2 of glass is provided with four longitudinal grooves 3,4,10 and 13 in which the discharge is located. The intermediate parts 7, 16, 17 and 18 of the inner element 2 which lie close to the lamp housing 1 and also the corresponding adjacent parts 7a, 16a, 17a and 18a of the lamp housing 1 are free of luminescent material and form so-called "Light exit windows". The parts of the wall of the grooves and the lamp casing facing the discharge are covered with luminescent powder. These parts of the grooves are designated 3a, 4a, 10a and 13a while the parts of the lamp casing located opposite the grooves are designated with 20,21,22 and 23 (also covered with luminescent powder).

Measured around the circumference of the lamp envelope, the width of the luminescent layers, such as the layer 20, is approximately equal to the width of the uncoated parts, such as the part 17a. In this way, light entering the hollow inner element can leave the lamp through the "light output windows" (16,16a) because these windows are free of luminescent powder.

The described lamp can be manufactured by sliding the cylindrical lamp housing 1 over the inner element 2 and then subsequently connecting their bottom ends sealingly to each other, e.g. by means of sealing glass. The grooved inner element 2 can be blown in a single working operation inside two facing cast blocks of graphite or chrome-nickel steel, in which the groove pattern is arranged. Depending on this track pattern, a compact lamp with a bent or folded discharge path comprising four or more parallel sections is obtained.

Fig. 4 shows a cross section near the base of a lamp 1a, the inner element 2a being provided with grooves similar to the lamp according to Fig. 3, the difference being that in this case the discharge path is folded five times between the electrodes 24 and 25, resulting in six parallel grooves, which extend in the longitudinal direction of the lamp. From the electrode 24 the discharge path goes upwards (ie in the direction vertically upwards towards the viewer), returns via the groove 26, goes via an opening near the foot or the base upwards again through the groove 27, downwards through the groove 28, then via an opening into the groove 29 and upwards through the groove 29 and finally down to the electrode 25. 446 574 - 5 Six intermediate windows are consequently formed in this lamp. In this embodiment, the discharge path becomes relatively long so that the operating voltage of the lamp increases and the relative electrode losses decrease. As a result, the efficiency of the lamp and electrical ballast for the same added power increase. In a practical embodiment, the housing of the lamp is approximately 8 cm long, while the diameter of the lamp housing (outer element) is approximately 6 cm. The total length of the url additive is approximately 40 cm. The grooves are approximately 0.9 cm deep. The width of the intermediate parts or end surfaces is approximately 1.2 cm. With the same luminescent material, noble gas mixture and noble gas pressure as in the lamp described with reference to Fig. 1, the efficiency was 60 lm / H at an applied power to the lamp of 20 N.

Fig. 5 shows a cross section of a lamp according to Fig. 3 but with a hollow reflecting element 30 arranged inside the inner element 2. This element consisting of reflective aluminum foil is grooved in the direction of the grooves and "windows" 7, 16, 17 and 18 so that an optimal reflection_of the light coming from the grooves takes place against said window. The tops of the pairs of grooves cooperating with the windows 16-20 are denoted by 30a, 30b, 30c and 30d, respectively. Inside the reflector element there is sufficient space to receive an electrical stabilization ballast 31, as shown by broken lines.

According to Fig. 6 ', a continuously helically shaped groove 34 is arranged in an outer element 32, the outlet having a run in the groove 34 and being delimited by the wall of the outer element 32 and the cylindrical hollow inner glass element 33. Only the parts of the walls of the outer and inner elements which enclose the addition web are covered with luminescent powder 35. The spiral-shaped parts of the walls which are not coated with luminescent powder are denoted by 36 and 37. These parts form light output windows through which the light generated by the layer 35 can leave the lamp without obstruction (see arrow). The lamp is provided with two electrodes 38 and 39 which are supported by glass tubes 41 and 42 and a sleeve 40 by means of which the lamp can be mounted in a luminaire for incandescent lamps. This sleeve contains e.g. a starting device and / or an electric ballast. In a practical embodiment, the diameter of the inner element 33 was 20 nm and the heavier diameter of the outer element 32 was approximately 60 spaces. The total length of the discharge path was approximately 60 cm. The middle portion 36 was approximately 1.0 cm wide. When using the previously mentioned luminescent materials and noble gases, the efficiency of the lamp became 65 lm / l-1 at a power supplied to the lamp of 30 H and a working voltage of 150 V.

In Figures 7 and 8, components corresponding to Figs. 3 (Figs. 1 and 2, respectively) have been provided with the same reference numerals as in this figure. In the cross section through a lamp according to the invention, which is shown in Fig. 7, the outer wall of the end surfaces of the inner element 2 has been provided with a light refraction profile (7b, 15b, 17b and 18b), which has a high transmission coefficient of light. This refractive profile has a 44ees74l plurality of ribs extending parallel to the discharge path (in the longitudinal direction of the lamp). The rib-shaped structure has the effect that the light rays emanating from the grooves 3, 4, 10 and 13 are refracted in such a way as a result of their prismatic effect that the lamp has an even light distribution. The angle Wi the profile between the uptrixtaae edges of adjacent ribs is approximately 12o °.

In the cross-section according to Fig. 8, the parts of the cylindrical outer glass element 1, which are located opposite the end surfaces, are provided on the outside with a refractive profile in the form of ribs. These profiles are denoted by 7c, 16c, 17c and 18c. Also in this embodiment the angle in the profile is approximately 1200.

Claims (10)

446 57-4 Patent claims. A low pressure mercury vapor discharge lamp comprising a hollow inner member (2) surrounded by a transparent outer member (1), the wall of at least one of the members having a groove (3, Å, 10, 13, 26-29.3 fi) while intermediate parts The elements (7, 16, 17, 17, 18) of this element located between the groove parts extend to or almost to the wall of the second element, a discharge path being defined by the groove and the second element wall and the wall parts of the two elements. defining said discharge path are covered by luminescent material (3a, üa, 10a, 13a, 20-23), characterized in that said intermediate parts (7, 16, 17, 18) located between the track parts are facing and stretching. parallel to the opposite portions (7a, 16a, 17a, 18a) of the wall of the second element, and that these intermediate portions and the opposite portions of the second element are free of luminescent material. The low-pressure mercury charge lamp according to claim 1, characterized in that there is a gap of not more than 2.0 mm between each intermediate part (7, 16, 17, 17) and its associated opposite part (7a, 16a, 17a, 18a). of the wall of the other element. 3. A low-pressure mercury discharge lamp according to claim 1 or 2, characterized in that the groove (BH) is helical. HRS. A low-pressure mercury vapor discharge lamp according to claim 1 or 2, characterized in that the groove portions (3, #, l0, l3,26-29) extend substantially in the longitudinal direction of the elongate lamp. 5. A low-pressure mercury vapor discharge lamp according to claim 1, 2,3 or Ä, characterized in that the inner element (2) is provided with said grooves (3, Å, 10, 13, 26-29) and that the outer element (1) is generally cylindrical. Low-pressure mercury vapor discharge lamp according to claim Ä or 5, characterized in that, measured along the circumference of the inner element (2), the width of the grooves (3,4, 10, 13, 26-29) is substantially equal to the said intermediate parts (7). , l6, l7, l8) width. 7. A low-pressure mercury discharge lamp according to claim 1, 2, 3, 2, 5, 6 or 6, characterized in that a light-reflecting element (30) is located inside the inner element (2) 446 574. A low-pressure mercury vapor discharge lamp according to claim 7, characterized in that the reflecting element (30) is knurled in the direction of the intermediate parts (7, 16, 17, 17) in the longitudinal direction. A low-pressure mercury vapor discharge lamp according to claim 7 or 8, characterized in that an electrical stabilization ballast is located inside the reflecting element (30). Low-pressure mercury vapor discharge lamp according to one of Claims 1 to 9, characterized in that the intermediate parts (7, 16, 17, 18) and / or the opposite wall parts (7a, 16a, 17a, 18a), which are located opposite the intermediate parts, of the second element has a refractive profile.